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Revision as of 17:31, 4 September 2012

Use this page to answer the questions on the safety page.

Potential safety issues our project could raise:

When designing the experiments the NRP-UEA-Norwich team would undertake they had to consider not only the safety of the researchers and others within the lab, but also the public and the environment. They had to consider carefully the organisms and chemicals they would be using within lab, how they would handle these safely and then dispose of them after to minimize their effect on the environment and the public.

Researcher safety

The University of East Anglia already has safety standards that have to be met, which included having basic safety training before starting wet lab work, as well as reading, understanding and signing relevant COSH forms for each potential lab procedure. Therefore, when designing experiments the NRP-UEA-Norwich team considered the risks associated and checked whether the COSH forms signed covered the procedures undertaken. The team also received training from advisors over the first few days of their time in the lab. They learnt what to do in emergencies, where to access the safety manual which is always within the lab, as well as being shown where to dispose of the different chemicals and used equipment. It is also vital that researchers within the university wear personal protective equipment (PPE), including lab coat, gloves and covered shoes. The members also wore protective face shields when using artificial UV light in the darkroom. In accordance with university regulation, the team was prohibited from eating, drinking or smoking in or near the lab. The team enjoyed their lunch well away from the lab, as well as being careful to wash their hands before leaving.

The lab facilities were designed to be safe for the team members, providing plenty of space and clean surfaces to work on. The lab was supplied with plastic handheld pipettes, and permanent pens; removing the need for use researchers to ever use their mouths during experimentation e.g. mouth pipettes and labels that require saliva to aid adhesion.

The team had originally thought it would be interesting to look at NO levels within salmonella, but decided later that this would result in a lot more safety concerns and complications. Therefore, the team decided to only use strains of "E.coli" (which they had all used within their university studies before and were allowed to handle within the lab) within our projects. NEB 5-alpha E.coli was use to characterize existing bio bricks, as well as BL21 pLysS E. coli cells and Alpha select gold E.coli. E.coli is a well-studied species of bacteria, with fairly predictable behavior, as well as being non-pathogenic (a biosafety level 1 bacteria). Therefore, all the students were able to use the E.coli within the university’s second year (category one and two) teaching labs.

Since the team’s project involves Nitric Oxide (NO) they had to consider the safety of the chemicals involved. It is important to note that all chemicals within the lab are supplied with a safety advice sheet that has been generated by the company it was manufactured by. NO has been classed as a dangerous gas which can be directly toxic to blood, lungs, pancreas and nervous system. Therefore, caution was taken when using NO within the lab. Its clear appearance makes indicating the presence of the gas difficult, increasing the likelihood of the gas being unintentionally inhaled. However, the gas has an odor allowing researchers to detect its presence and act accordingly. To minimize this risk, NO was handled within fume cupboards and chambers, reducing researcher exposure to any released NO.

In reality, although the team aimed to test the hybrid promoter with NO (as required for therapeutic effects) due to time restrictions this was inappropriate. If the team had more time they envisaged testing the comparator circuit using NO after its analysis when attached to promoters that respond to safer and simpler inducer molecules, such as arabinose. This would have been an ideal method of characterizing the comparator circuit, as well as a method of gaining experience in the relevant procedures before using more toxic chemicals.

Another safety concern was the use of Ethidium Bromide (EtBr) during the agrose gel staining. Ethidium Bromide is a known carcinogen, therefore the team took care to follow the university's specific guidelines on working with carcinogens (File:UEA Rules for working with carcinogens in laboratories.pdf), which include the use of protective equipment, gloves and the appropriate disposal of waste in order to minimize researcher exposure.

In the preliminary discussions in which the experiments the team would carry out were discussed, careful consideration was taken to choose appropriate equipment. They considered the equipment’s safety to the researcher, as well as the practicality and quality of results gained. The team members used most of the discussed equipment and procedures already used during their first two years of their undergraduate degree. However, there were a few procedures such as NanoDrop spectrophotometery and fluorometery that had not been used by the team before. Therefore the team members received training from experienced members of staff in order to avoid accidents that could damage the researchers or the machine itself. Finally, there were always more experienced scientists present within the lab to advise the team further on how to use equipment safely.

Public safety

The team always removed their lab coats and gloves, as well as washed their hands before leaving the lab. This reduced the chance of bringing harmful bacteria or substances outside the laboratory environment. The team also took care to keep the laboratory windows shut, in order to reduce exposure to the outside world.

All contaminated waste was autoclaved on site before being collected and disposed of under controlled conditions for cleaning for reuse.

The team felt that it was important that the public were given the opportunity to understand and ask about procedures used in the laboratory, so they could form informed opinions about the safety and ethical implications of the teams work. The team took the opportunity at their public engagement project to explain the procedures they used in full detail.

At this public engagement event the team took transformed E.coli samples to the venues and public safety was a priority. Therefore, the plates were maintained in a UV box behind a sheet of plastic, limiting public physical interaction with the laboratory specimens. These plates were also sealed extensively using parafilm and were kept well away form any part of the venue holding or serving food products.

Environmental safety

Data safety sheets that come with chemicals explain how to dispose of the chemicals correctly. These guidelines were adhered to rigidly since the local water providing company, Anglia water, carry out routine random samples on what is poured down the sink drains, and if a certain volume (volume is unknown to university, which encourages them not to put any waste down the sink) of listed chemicals are found, then the university is fined.

There is a very low risk of damage to the environment as all bacteria will be stored safely within the lab. However, if the bacteria was to unexpectedly be released, there is very little threat on the environment, since the bacteria are standard autotrophic laboratory stains and therefore unlikely to survive. The “E.coli” stains used are also unlikely to replicate and therefore spread. Finally, due to using plasmids with a narrow host range horizontal gene transfer between bacteria within the environment is also very unlikely, as plasmids would not replicate if transferred to other organisms.

Safety issues our BioBrick parts could raise:

The first bio bricks made by the NRPUEA iGEM team are hybrid promoters which are composed of a mammalian promoter fused to a bacteria promoter. The team has done this in both orientations. Since this is a new concept they are not well characterized therefore providing saftey concerns , as it is not fully known how the promoters will interact together. However, the team have not submitted any issues in the registry as no issues have arisen yet, and there are no specific concerns within the DNA sequence and both individual promoters are well characterized and understood.

The comparator circuit biobrick is also a new construct, therefore again not well characterized,this could potentially join to functional genes and effect their gene regulations. however, as with the hybrid promoter these biobricks are being placed in standard BSL1 laboratory autotrophic strains of "E.coli", and therefore unlikely to be able to survive outside the lab. therefore the team has not entered issues in to the registry, as no evidence of concern has arisen yet. but if issues arise during characterization of the comparator circuit, these will be submitted.

The team handled these saftey issues by following and being in compliance with both the government saftey standards, as well as the university saftey standards. Also the team insert the biobricks in to the narrow host range plasmid, produced by iGEM, reducing chances of horizontal gene transfer.

future iGEM teams could increase chances of saftey, by connecting the hybrid promoter to suicide gene, therefore meaning that if the unlikely happened and the transformed cells were released in the the environment and the plasmid containing the biobricck was taken up up by another bacteria, this bacteria would be destroyed and therefore reduce chance of spreading.

The University of East Anglia's biosafety review board

UEA considers both staff and student safety and has its own health and safety polices and biosaftey rules that must be followed:File:UEA GMO rules.pdf,File:UEA statment of health and saftey policy.pdfandFile:UEA Microbiological saftey rules.pdf. These have been created to follow the guidelines and biosafty rules that have to be considered in the united kingdom as seen here http://www.hse.gov.uk/biosafety/gmo/law.htm . All our projects are in compliance with both the university requirements and national regulations.The university has its own biosafety committee in which the responsibilities of different aspects of safety are split between departments and staff.Dr Andrew Hemmings is the BIO safety officer at UEA. Andrew spoke to members of the team about the project and discussed whether our COSH forms covered the processes carried out. The team then discussed their project further with other members of staff including Dr Mark Coleman, university GMO safety officer, and Dr Gabriella Kelemen, university microbial safety officer.

When speaking to the UEA biosafty team there was no concern with the processes being carried out and the bacteria being used. when the team talked to GMO safety officer,Dr Mark Coleman, about the safety of the biobricks they intended to create he said "there is a highly improbable chance this project poses a significant risk to either human health or the environment".

Do you have any other ideas how to deal with safety issues that could be useful for future iGEM competitions? How could parts, devices and systems be made even safer through biosafety engineering?

Since the team started looking at NO, and we soon became clear of the dangers of unintentional exposure to NO. Therefore, we would hope that using systems similar to our comparator sensor, NO sensors will be produced that are in the form of a sheet of paper and can be placed on the wall of labs, and buildings ect, to indicate excess levels of NO.

Future iGEM teams could aim to reduce the chance of horizontal gene transfer further by reducing the adherence between the transformed cells and others, or via the Prevention of transformations without inducing competency. This would be a procedure to prevent some cases of antibiotic genes being passed through between bacterial species.